Mathematical Simulation of Heat Transfer in Thermally Magnetised Oldroyd-B Fluid in Sakiadis Rheology with a Heat Reservoir

Sakiadis rheology of a generalised polymeric material, as well heat source or sink and magnetic field, are all part this study. Thermal radiations have been introduced into the convective heating process. The translation physical situation set nonlinear equations was achieved through mathematical modelling. To convert resulting partial differential equation ordinary equations, appropriate transformations used. velocity temperature profiles generated both analytically by HAM numerically Runge–Kutta method (RK-4). In order to analyse behaviour quantities involved, numerical graphical depictions offered. show that acquired findings correct, system error analysis has flux study shown using bar charts. For essential factors local Nusselt number Skin friction calculated in tabular form. fluid particles’ molecular mobility slowed due field porosity, transfer rates were demonstrated be lowered when porosity effects present. This regulating property applications MHD ion propulsion power production, electromagnetic casting metals, etc. Furthermore, internal absorption generation diametrically opposed impacts on temperature. novelty present is no one investigated flow thermal convection magnetised Oldroyd-B terms reservoir across porous sheet. limited circumstances, satisfactory match revealed collected values compared existing work published corroborating current attempt. expected applicable wide range technical industrial processes, including steel extrusion, wire protective layers, fiber rolling, fabrication, polythene stuff such broadsheet, fiber, stainless sheets, even process depositing thin layer where sheet squeezed.